Apparatus and method for signaling system information

ABSTRACT

The present disclosure relates to a communication method and system for converging a 5 th -generation (5G) communication system for supporting higher data rates beyond a 4 th -generation (4G) system with a technology for internet of things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. A method for receiving system information (SI) by a user equipment (UE) in a wireless communication system is provided. The method includes receiving, from a base station (BS), first type SI associated with SI which is essential for communication with the BS, transmitting, to the BS, a physical random access channel (PRACH) preamble based on the first type SI, receiving, from the BS, a random access response (RAR) message, and receiving, from the BS, second type SI associated with at least one SI which the UE needs.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application is a continuation application of prior application Ser.No. 16/229,974, filed on Dec. 21, 2018, which is a continuationapplication of prior application Ser. No. 15/443,307, filed on Feb. 27,2017, which has issued as U.S. Pat. No. 10,455,621 on Oct. 22, 2019 andwas based on and claimed priority under 35 U.S.C § 119(e) of a U.S.Provisional application Ser. No. 62/301,016, filed on Feb. 29, 2016, inthe U.S. Patent and Trademark Office, and of a U.S. Provisionalapplication Ser. No. 62/334,706, filed on May 11, 2016, in the U.S.Patent and Trademark Office, the disclosure of each of which isincorporated by reference herein in its entirety.

TECHNICAL FIELD

The present disclosure relates to a wireless communication system. Moreparticularly, the present disclosure relates to an apparatus and methodfor transmitting and receiving system information.

BACKGROUND

To meet the demand for wireless data traffic having increased sincedeployment of fourth generation (4G) communication systems, efforts havebeen made to develop an improved fifth generation (5G) or pre-5Gcommunication system. Therefore, the 5G or pre-5G communication systemis also called a ‘Beyond 4G Network’ or a ‘Post long term evolution(LTE) System’. The 5G communication system is considered to beimplemented in higher frequency (mmWave) bands, e.g., 60 GHz bands, soas to accomplish higher data rates. To decrease propagation loss of theradio waves and increase the transmission distance, the beamforming,massive multiple-input multiple-output (MIMO), full dimensional MIMO(FD-MIMO), array antenna, an analog beam forming, large scale antennatechniques are discussed in 5G communication systems. In addition, in 5Gcommunication systems, development for system network improvement isunder way based on advanced small cells, cloud radio access networks(RANs), ultra-dense networks, device-to-device (D2D) communication,wireless backhaul, moving network, cooperative communication,coordinated multi-points (CoMP), reception-end interference cancellationand the like. In the 5G system, hybrid frequency shift key (FSK) andquadrature amplitude modulation (QAM) modulation (FQAM) and slidingwindow superposition coding (SWSC) as an advanced coding modulation(ACM), and filter bank multi carrier (FBMC), non-orthogonal multipleaccess (NOMA), and sparse code multiple access (SCMA) as an advancedaccess technology have been developed.

The Internet, which is a human centered connectivity network wherehumans generate and consume information, is now evolving to the Internetof things (IoT) where distributed entities, such as things, exchange andprocess information without human intervention. The Internet ofeverything (IoE), which is a combination of the IoT technology and theBig Data processing technology through connection with a cloud server,has emerged. As technology elements, such as “sensing technology”,“wired/wireless communication and network infrastructure”, “serviceinterface technology”, and “Security technology” have been demanded forIoT implementation, a sensor network, a machine-to-machine (M2M)communication, machine type communication (MTC), and so forth have beenrecently researched. Such an IoT environment may provide intelligentInternet technology services that create a new value to human life bycollecting and analyzing data generated among connected things. IoT maybe applied to a variety of fields including smart home, smart building,smart city, smart car or connected cars, smart grid, health care, smartappliances and advanced medical services through convergence andcombination between existing information technology (IT) and variousindustrial applications.

In line with this, various attempts have been made to apply 5Gcommunication systems to IoT networks. For example, technologies such asa sensor network, MTC, and M2M communication may be implemented bybeamforming, MIMO, and array antennas. Application of a cloud RAN as theabove-described Big Data processing technology may also be considered tobe as an example of convergence between the 5G technology and the IoTtechnology.

In the recent years, several broadband wireless technologies have beendeveloped to meet the growing number of broadband subscribers and toprovide more and better applications and services. The second generationwireless communication system has been developed to provide voiceservices while ensuring the mobility of users. Third generation wirelesscommunication system supports not only the voice service but also dataservice.

In recent years, the fourth wireless communication system has beendeveloped to provide high-speed data service. However, currently, thefourth generation wireless communication system suffers from lack ofresources to meet the growing demand for high speed data services. Sofifth generation wireless communication system is being developed tomeet the growing demand for high speed data services, supportultra-reliability and low latency applications and support massivemachine type communication.

In the fourth generation wireless communication system, enhanced node B(eNB) or base station (BS) in cell broadcast system information. Systeminformation is structured into master information block (MIB) and a setof system information blocks (SIBs). MIB consists of system frame number(SFN), downlink system bandwidth and physical hybrid automatic repeatrequest (ARQ) feedback indicator channel (PHICH) configuration. An MIBis transmitted every 40 ms. It is repeated every 10 ms wherein the firsttransmission occurs in subframe #0 when SFM mod 4 equals zero. MIB istransmitted on physical broadcast channel SIB Type 1 carries cellindemnity, tracking area code, cell barring information, value tag(common for all scheduling units), and scheduling information of otherSIBs. SIB 1 is transmitted every 80 ms in subframe #5 when SFN mod 8equals zero. SIB 1 is repeated in subframe #5 when SFN mod 2 equalszero. SIB 1 is transmitted on Physical downlink shared channel OtherSIBs (SIB 2 to SIB 19) are transmitted in system information (SI)message wherein scheduling info of these SIBs are indicated in SIB 1.SIBs having same periodicity can be transmitted in one SI message. SImessage is broadcasted on Physical downlink shared channel. VariousSIBs, their usage and typical size is indicated in Table 1 below.

TABLE 1 System Information in 4G System SIB Type Content SIB Size SIB 1Cell ID, value tag & Scheduling info  ~500 bits SIB 2 AC-Barring, RACHInfo  2216 bits (Max) SIB 3 Common Cell reselection info & intra  ~100bits frequency cell reselection parameters SIB 4 Intra frequencyneighbor cell info  ~750 bits SIB 5 Inter frequency cell reselectioninformation ~1000 bits SIB 6 UTRA cell reselection information ~1000bits SIB 7 GERAN cell reselection information ~1000 bits SIB 8 CDMA 2000cell reselection information  2216 bits (Max) SIB 9 Home eNB Info   ~56bits SIB 10 ETWS Primary Notification  2216 bits (Max) SIB 11 ETWSSecondary Notification  2216 bits (Max) SIB 12 CMAS Notification  2216bits (Max) SIB 13 MBMS Information to acquire MBMS  ~300 bits Controlinformation SIB 14 Extended Access Class Barring Information  ~100 bitsSIB 15 MBMS Service Area Identifiers of the  2216 bits (Max) current andneighboring frequencies SIB 16 UTC Time   ~60 bits SIB 17 Informationfor traffic steering between  2216 bits (Max) E-UTRAN and WLAN SIB 18Intra Frequency D2D Communication  2216 bits (Max) Information SIB 19Intra/inter frequency D2D Discovery  2216 bits (Max) Information

User equipment (UE) acquires the system information at cell selection,cell reselection, after handover completion, after entering evolved UMTSterrestrial radio access (E-UTRA) from another radio access technology(RAT), upon re-entering service area, upon receiving a notification(paging), and upon exceeding the maximum validity duration (3 hour).

In radio resource control (RRC) idle state, UE needs to acquire MIB, SIB1, SIB 2 to SIB 5, SIB 6 to SIB 8 (depending on RAT supported), SIB 17(if LTE-wireless local area network (WLAN) interworking (IWK) issupported), and SIB 18 to SIB 19 (if D2D is supported). In RRC connectedstate, UE needs to acquire MIB, SIB 1, SIB 2, SIB 8 (depending on RATsupported), SIB 17 (if LTE-WLAN IWK is supported), and SIB 18 to SIB 19(if D2D is supported). System information acquired and stored isconsidered invalid of if value tag in received SIB 1 is different fromthe one in stored SI.

System information can be changed and is notified as follows: Change isnotified through paging message (in RRC_IDLE or RRC_CONNECTED) withcause systemInfoModification to let UE know that some SI is changing inthe next modification period. Modification period boundaries are interms of SFN such that SFN mod modificationPeriod=0. Change of SI occursat specific radio frames. Notification of changes in modification periodN will be reflected in N+1. SIB 1 also carries value tag to indicatechange in SI. UE finds the change in SI by looking at value tag in SIB 1at the end modificationPeriod (if missed checking page) or receivingpaging with systeminfoModification.

The above information is presented as background information only toassist with an understanding of the present disclosure. No determinationhas been made, and no assertion is made, as to whether any of the abovemight be applicable as prior art with regard to the present disclosure.

SUMMARY Technical Problem

One of the issues in current method of transmitting system informationusing the master information block (MIB)/system information blocks(SIBs) is that MIB/SIBs are periodically broadcasted irrespective ofwhether a user equipment (UE) is there in cell or not; whether any UE incell needs that information. In case of small cell deployment,broadcasting all these SIBs periodically is unnecessary and leads tosignificant wastage of resources and increased energy consumption.

Next Generation communication system is considering carrier frequencyranges up to 100 GHz. At higher frequencies, beamforming is essential tocompensate for path loss. One transmission beam cannot provide the fullcell coverage. Multiple transmission beams are needed. In order tobroadcast the system information, system information needs to betransmitted using multiple transmission beams by switching atransmission (TX) beam across multiple time slots. Overhead(time/frequency resources) of transmission of system information usingbeamforming is N times more than transmission of system informationwithout beamforming where ‘N’ is the number of transmission beams. Thetransmission resources remaining after resources consumed fortransmission of system information may be used for data scheduling for auser in the direction of the downlink (DL) transmission beam. Therefore,if more time/frequency resources are consumed for transmission systeminformation then user data scheduling becomes restrictive andinflexible.

Additionally UE has to reacquire the system information when it movesfrom one cell to another cell. This leads to increased power consumptionfor mobile UEs. So an enhanced method of signaling system information isneeded.

Technical Solution

Aspects of the present disclosure are to address at least theabove-mentioned problems and/or disadvantages and to provide at leastthe advantages described below. Accordingly, an aspect of the presentdisclosure is to provide a method for receiving system information (SI)by a UE in a wireless communication system. The method includesreceiving, from a base station (BS), first type SI associated with SIwhich is essential for communication with the BS, transmitting, to theBS, a physical random access channel (PRACH) preamble based on the firsttype SI, receiving, from the BS, a random access response (RAR) message,and receiving, from the BS, second type SI associated with at least oneSI which the UE needs.

In accordance with an aspect of the present disclosure, a method fortransmitting system information (SI) by a base station (BS) in awireless communication system is provided. The method includestransmitting, to a user equipment (UE), first type SI associated with SIwhich is essential for communication with the UE, receiving, from theUE, a physical random access channel (PRACH) preamble based on the firsttype SI, transmitting, to the UE, a random access response (RAR)message, and transmitting, to the UE, second type SI associated with atleast one SI which the UE needs.

In accordance with an aspect of the present disclosure, a user equipment(UE) for receiving system information (SI) in a wireless communicationsystem is provided. The UE includes a transceiver configured to transmitand receive a signal, and at least one processor configured to controlreceiving, from a base station (BS), first type SI associated with SIwhich is essential for communication with the BS, control transmitting,to the BS, a physical random access channel (PRACH) preamble based onthe first type SI, control receiving, from the BS, a random accessresponse (RAR) message, and control receiving, from the BS, second typeSI associated with at least one SI which the UE needs.

In accordance with an aspect of the present disclosure, a base station(BS) for transmitting system information (SI) in a wirelesscommunication system is provided. The BS includes a transceiverconfigured to transmit and receive a signal, and at least one processorconfigured to control transmitting, to a user equipment (UE), first typeSI associated with SI which is essential for communication with the UE,control receiving, from the UE, a physical random access channel (PRACH)preamble based on the first type SI, control transmitting, to the UE, arandom access response (RAR) message, and control transmitting, to theUE, second type SI associated with at least one SI which the UE needs.

Advantageous Effects

In accordance with an aspect of the present disclosure, a user equipment(UE) and a BS are provided. The UE and BS are capable of signalingsystem information efficiently in a wireless communication system.

Other aspects, advantages, and salient features of the disclosure willbecome apparent to those skilled in the art from the following detaileddescription, which, taken in conjunction with the annexed drawings,discloses various embodiments of the present disclosure.

BRIEF DESCRIPTION OF DRAWINGS

The above and other aspects, features, and advantages of certainembodiments of the present disclosure will be more apparent from thefollowing description taken in conjunction with the accompanyingdrawings, in which:

FIG. 1 illustrates a method for acquiring system information accordingto an embodiment of the present disclosure;

FIG. 2 illustrates a method for categorizing system informationparameters into system information blocks (SIBs) according to anembodiment of the present disclosure;

FIG. 3 illustrates a method for categorizing system informationparameters into SIBs according to an embodiment of the presentdisclosure;

FIG. 4 illustrates a method for categorizing system informationparameters into system information set according to an embodiment of thepresent disclosure;

FIG. 5 illustrates a method for categorizing system informationparameters into system information set according to another embodimentof the present disclosure;

FIG. 6 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 7 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 8 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 9 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 10 illustrates a method for indicating in broadcasted essentialsystem information whether other system information is broadcasted ornot according to an embodiment of the present disclosure;

FIG. 11 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 12 illustrates a method for indicating in broadcasted essentialsystem information whether other system information is broadcasted ornot according to another embodiment of the present disclosure;

FIG. 13 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 14 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 15 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure;

FIG. 16 illustrates a method for providing system information within atime window according to an embodiment of the present disclosure;

FIG. 17 illustrates a method for providing system information bymonitoring a time window in one or more periods according to anembodiment of the present disclosure;

FIG. 18 illustrates a method for configuring system information area IDaccording to an embodiment of the present disclosure;

FIG. 19 illustrates a method for indexing system information parametersaccording to an embodiment of the present disclosure; and

FIG. 20 illustrates a method for configuring a system informationconfiguration identification (ID) according to an embodiment of thepresent disclosure.

Throughout the drawings, like reference numerals will be understood torefer to like parts, components, and structures.

DETAILED DESCRIPTION

The following description with reference to the accompanying drawings isprovided to assist in a comprehensive understanding of variousembodiments of the present disclosure as defined by the claims and theirequivalents. It includes various specific details to assist in thatunderstanding but these are to be regarded as merely exemplary.Accordingly, those of ordinary skill in the art will recognize thatvarious changes and modifications of the various embodiments describedherein can be made without departing from the scope and spirit of thepresent disclosure. In addition, descriptions of well-known functionsand constructions may be omitted for clarity and conciseness.

The terms and words used in the following description and claims are notlimited to the bibliographical meanings, but, are merely used by theinventor to enable a clear and consistent understanding of the presentdisclosure. Accordingly, it should be apparent to those skilled in theart that the following description of various embodiments of the presentdisclosure is provided for illustration purpose only and not for thepurpose of limiting the present disclosure as defined by the appendedclaims and their equivalents.

It is to be understood that the singular forms “a,” “an,” and “the”include plural referents unless the context clearly dictates otherwise.Thus, for example, reference to “a component surface” includes referenceto one or more of such surfaces.

FIG. 1 illustrates a method for acquiring system information accordingto an embodiment of the present disclosure.

Referring to FIG. 1, in an embodiment of the present disclosure the userequipment (UE) can acquire the system information as shown in FIG. 1.System information (SI) is categorized into two categories: The firstcategory (also referred as minimum SI or essential SI) comprises of oneor more system information which are broadcasted periodically by thecell and/or transport, routing, and packaging (TRP) information. Thesecond category (also referred as Other SI) comprises of one or moresystem information which are provided on demand or can be broadcastedperiodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The firstcategory of system information includes at least system frame number(SFN), list of public land mobile network (PLMN) identifications (IDs),Cell ID, cell camping parameters, etc. The second category of systeminformation includes the system information not included in firstcategory. The first category (also referred as minimum SI or essentialSI) of system information is periodically broadcasted by the cell and/orTRP.

In operation 110, UE acquires first category (also referred as minimumSI or essential SI) from broadcasted information. Network signals infirst category of system information i.e. in Minimum SI or essential SIwhether the system information in the second category is periodicallybroadcasted or provided on demand.

For example, in case of heterogeneous network comprises of macro celland small cells, macro cell may indicate that system information isbroadcasted whereas small cells may indicate that system information isnot broadcasted. In another example, if there are several requests forsystem information provided on demand then network may start tobroadcast the system information instead of providing on demand.

Minimum SI or essential SI may include an indication which indicatesthat all SIs of second category of system information are periodicallybroadcasted or are provided on demand. Alternately, minimum SI oressential SI may include a separate indication for each SI (e.g. systeminformation block (SIB)) or set of SIs (i.e. SIBs) wherein eachindication indicates whether the associated SI or set of SIs areperiodically broadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI message wherein each SI message carries one ormore SIs (i.e. SIBs). The indication associated with an SI messageindicates whether SIs associated with that SI message are broadcasted orprovided on demand. Mapping of SI message to SIBs in included in minimumSI or essential SI.

In order to acquire a SI of second category, UE first determines whetherthat SI is periodically broadcasted or provided on demand. UE determinesthis based on indication included in first category (also referred asminimum SI or essential SI) of system information. If first category(also referred as minimum SI or essential SI) of system informationindicates that SI which UE wants to acquire is periodically broadcasted(or not provided on demand) then UE acquires the SI from the periodicbroadcast using the scheduling information included in first category(also referred as minimum SI or essential SI), in operation S110. Iffirst category (also referred as minimum SI or essential SI) of systeminformation indicates that SI which UE wants to acquire is notperiodically broadcasted (or provided on demand) then UE sends requestto base station (BS) to receive that SI.

In order to receive one or more system information provided on demand,in operation S120, UE transmits random access preamble (PRACH). In anembodiment, PRACH preambles or PRACH opportunities (i.e. time/frequencyresources) for requesting system information can be different from thePRACH preambles or PRACH opportunities for other purposes. This canminimize impact to random access load because of SI requests. PRACHpreambles or PRACH opportunities (i.e. time/frequency resources) forobtaining system information can be predefined or signaled by network infirst category (also referred as minimum SI or essential SI) of systeminformation.

On receiving the random access preamble, in operation S130, BS transmitsa random access response (RAR) and the RAR includes an uplink (UL) grantfor transmitting the SI request message. The RAR may also include timingadvance and/or back off indicator and or preamble identifier (identifiesthe PRACH preamble).

UE validates that the RAR corresponds to PRACH transmitted by it. If thevalidation is successful, in operation S140, the UE transmits an SIrequest message in the UL grant. The SI request message indicates one ormore system information (e.g. SIBs) which UE needs or indicates one ormore sets of system information which the UE needs or indicates service(e.g. enhanced mobile broadband (eMBB), mobile telecommunicationscompany (MTC), ultra-reliable and low-latency (URLL), etc.) for which UEneeds system information or UE type. UE may transmit its UE ID (i.e.SAE-temporary mobile subscriber identity (S-TMSI), cell-radio networktemporary identifier (C-RNTI), random access-radio network temporaryidentifier (RA-RNTI), etc.) along with the SI request message.

In response to the SI request, in operation S150, BS transmitsSI-response wherein the SI-response includes the requested systeminformation. SI response can be broadcasted or provided in unicastmanner. Scheduling control information indicating the SI-response can bemasked with UE's ID (e.g. C-RNTI, RA-RNTI) or a pre-defined ID (e.g.system information-radio network temporary identifier (SI-RNTI)).Pre-defined ID can be different for different system information orsystem information set or service or UE type.

One or more SIs (i.e. SIBs) requested by UE are provided within sometime window (i.e. SI Response Window) after sending the SI request.After sending the SI request the UE listens to new radio-physicaldownlink control channel (NR-PDCCH) in SI Response Window for receivingthe requested SIBs. If UE does not receive the requested SIBs within theSI Response Window then UE may retransmit the SI request. The length ofSI response window is provided in minimum SI or essential SI.Alternately, after sending the SI request, for receiving the requestedSIB, UE monitors the SI window of requested SIB in one or more SIperiods of that SIB. The scheduling information for other SI includingSIB type, validity information, periodicity, SI-window information canbe provided in minimum SI irrespective of whether Other SI isperiodically broadcasted or provided on demand. In one embodiment, UEfirst checks for SI response in SI response window and if not receivedit monitors the SI window for receiving the requested SIs.

In one embodiment, evolved node B (eNB) may provide the requested systeminformation for one or more cells and/or TRPs. ENB may indicate thecells and/or TRPs for which system information provided in SI responseis applicable. As a result the UE does not need to request for systeminformation when the UE changes cell and/or TRP. After the cell and/orTRP change, if the UE does not have system information for the new celland/or TRP then UE request for system information.

In another embodiment of the present disclosure, BS can indicatesupported SI(s) in essential system information. UE can then request oneor more of the supported SIs which are provided on demand using themethod (FIG. 1) explained earlier. In an embodiment, a defaultconfiguration for system information can be defined which the UE usesuntil it obtains them from the cell.

In another embodiment, a cell may broadcast some of the SIs in the firstcategory of system information. The remaining SIs in the first categoryof system information of a cell can be broadcasted or provided on demandby another cell. In the request, UE may include information (e.g. cellID, frequency, cell index, etc.) about the cell for which it isrequesting SI.

UE can indicate the needed system information in SI-Request using one ofthe following options (Option 1˜Option 5):

Option 1:

FIG. 2 illustrates a method for categorizing system informationparameters into SIBs according to an embodiment of the presentdisclosure.

Referring to FIG. 2, system information parameters are categorized intoSIBs. In SI request, a bitmap of size N bits is included wherein eachbit corresponds to an SIB. Bit corresponding to an SIB can be set to oneto indicate that UE needs that SIB or Bit corresponding to an SIB can beset to zero to indicate that UE needs that SIB. Alternately, instead ofbitmap, UE can include a list of SIBs in SI-request.

Option 2:

FIG. 3 illustrates a method for categorizing system informationparameters into SIBs according to another embodiment of the presentdisclosure.

Referring to FIG. 3, system information parameters are categorized intoSIBs. SIBs are then grouped into an SIB set (or SI message) wherein eachset comprises one or more SIBs.

An SIB can be present in more than one SIB set. Grouping of SIBs intoSIB set can be done based on service (e.g. mobile broadband (MBB), URLL,mobile telecommunications company (MTC), device to device (D2D),D2D-discovery, D2D-Communication, vehicle-to-everything (V2X),vehicle-to-vehicle (V2V) etc.) or UE type (MTC UE, MBB UE, D2D UE,etc.).

In SI request, a bitmap of size P bits is included wherein each bitcorresponds to a SIB set. Bit corresponding to a SIB set can be set toone to indicate that UE needs that SIB. Alternately, instead of bitmap,UE can include a list of SIB set in SI-request.

Option 3:

FIG. 4 illustrates a method for categorizing system informationparameters into system information set according to an embodiment of thepresent disclosure.

Referring to FIG. 4, system information parameters are categorized intosystem information set. Grouping of system information parameters intosystem information set can be done based on service (e.g. MBB, URLL,MTC, D2D, D2D-discovery, D2D-Communication, V2X, V2V etc.) or UE type(MTC UE, MBB UE, D2D UE, etc.). In SI request, a bitmap of size P bitsis included wherein each bit corresponds to a system information set.Bit corresponding to system information set can be set to one toindicate that UE needs that system information set. Alternately, insteadof bitmap, UE can include a list of SI sets in SI-request.

Option 4:

FIG. 5 illustrates a method for categorizing system informationparameters into system information set according to another embodimentof the present disclosure.

Referring to FIG. 5, there is pre-defined mapping between one or moresystem information parameters and service. In SI request, a bitmap ofsize N bits is included wherein each bit corresponds to a service. Bitcorresponding to service can be set to one to indicate that UE needssystem information for this service. Alternately, instead of bitmap, UEcan include a list of one or more services in SI-request wherein eachservice can be identified by a service type.

Option 5:

In this method, UE can indicate UE type in SI request. UE type indicatesthe service supported by the UE. There is pre-defined mapping betweenone or more system information parameters and service. So on receivingthe SI request with UE type, BS can know the system informationparameters needed by UE.

FIG. 6 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure.

Referring to FIG. 6, in another embodiment of the present disclosure theUE can acquire the system information as shown in FIG. 6. Systeminformation is categorized into two categories: The first category (alsoreferred as minimum SI or essential SI) comprises of one or more Systeminformation which are broadcasted periodically by the cell and/or TRP.The second category (also referred as Other SI) comprises of one or moresystem information which is provided to UE on demand or can bebroadcasted periodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The firstcategory of system information includes at least SFN, list of PLMN IDs,Cell ID, cell camping parameters, etc. The second category of systeminformation includes the system information not included in firstcategory.

The first category (also referred as minimum SI or essential SI) ofsystem information is periodically broadcasted by the cell and/or TRP.In operation S610, UE acquires first category (also referred as minimumSI or essential SI) of system information from broadcasted information.Network signals in first category of system information i.e. in MinimumSI or essential SI whether the system information in the second categoryis periodically broadcasted or provided on demand.

For example, in case of heterogeneous network comprises of macro celland small cells, macro cell may indicate that system information isbroadcasted whereas small cells may indicate that system information isnot broadcasted. In another example, if there are several requests forsystem information provided on demand then network may start tobroadcast the system information instead of providing on demand. MinimumSI or essential SI may include in indication which indicates that allSIs of second category of system information are periodicallybroadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI (e.g., SIB) or set of SIs (i.e., SIBs) whereineach indication indicates whether the associated SI or set of SIs areperiodically broadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI message wherein each SI message carries one ormore SIs (i.e., SIBs). The indication associated with an SI messageindicates whether SIs associated with that SI message are broadcasted orprovided on demand. Mapping of SI message to SIBs in included in minimumSI or essential SI. In order to acquire a SI of second category, UEfirst determines whether that SI is periodically broadcasted or providedon demand. UE determines this based on indication included in firstcategory (also referred as minimum SI or essential SI) of systeminformation.

If first category (also referred as minimum SI or essential SI) ofsystem information indicates that SI which UE wants to acquire isperiodically broadcasted (or not provided on demand) then UE acquiresthe SI from the periodic broadcast using the scheduling informationincluded in first category (also referred as minimum SI or essential SI)of system information. If first category (also referred as minimum SI oressential SI) of system information indicates that SI which UE wants toacquire is not periodically broadcasted (or provided on demand) then UEsends request to BS to receive that SI.

In order to receive one or more system information provided on demand,in operation S620, UE transmits random access preamble. In anembodiment, PRACH preambles or PRACH opportunities (i.e. time/frequencyresources) for requesting system information can be different from thePRACH preambles or PRACH opportunities for other purposes. This canminimize impact to random access load because of SI requests. PRACHpreambles or PRACH opportunities (i.e. time/frequency resources) forobtaining system information can be predefined or signaled by network infirst category (also referred as minimum SI or essential SI) of systeminformation.

On receiving the random access preamble, in operation S630, BS transmitsa RAR and RAR includes UL grant for transmitting the SI request message.RAR may also include timing advance and/or back off indicator and orpreamble identifier (identifies the PRACH preamble).

UE validates that RAR corresponds to PRACH transmitted by it. If thevalidation is successful, in operation S640, UE transmits SI requestmessage in the UL grant. UE may not indicate which system information isneeded by UE. The carrier on which UE sends SI request supports oneservice. UE indicates that it needs system information. BS providessystem information for the service supported on carrier. There can bepre-defined mapping between carrier and service.

Alternately, service supported can be indicated in first category (alsoreferred as minimum SI or essential SI) of system information. Inoperation S650, SI response can be broadcasted or provided in unicastmanner. Scheduling control information indicating the SI-response can bemasked with UE's ID (e.g. C-RNTI, RA-RNTI) or a pre-defined ID (e.g.,SI-RNTI). Pre-defined ID can be different for different systeminformation or system information set or service or UE type.

One or more SIs (i.e., SIBs) requested by UE are provided within sometime window (i.e. SI Response Window) after sending the SI request.After sending the SI request, the UE listens to NR-PDCCH in SI ResponseWindow for receiving the requested SIBs. If UE does not receive therequested SIBs within the SI Response Window then UE may retransmit theSI request.

The length of SI response window is provided in minimum SI or essentialSI. Alternately, after sending the SI request, for receiving therequested SIB, UE monitors the SI window of requested SIB in one or moreSI periods of that SIB. The scheduling information for other SIincluding SIB type, validity information, periodicity, SI-windowinformation can be provided in minimum SI irrespective of whether OtherSI is periodically broadcasted or provided on demand. In one embodiment,UE first checks for SI response in SI response window and if notreceived it monitors the SI window for receiving the requested SIs.

In an embodiment, eNB may provide the requested system information forone or more cells and/or TRPs. ENB may indicate the cells and/or TRPsfor which system information provided in SI response is applicable. As aresult, the UE does not need to request for system information when theUE changes cell and/or TRP. After the cell and/or TRP change, if the UEdoes not have system information for the new cell and/or TRP then UErequest for system information.

In another embodiment of the present disclosure, BS can indicatesupported SI(s) in essential system information. UE can then request oneor more of the supported SIs using the method (FIG. 6) explainedearlier. In an embodiment, a default configuration for systeminformation can be defined which the UE uses until it obtains them fromthe cell.

In another embodiment, a cell may broadcast some of the SIs in the firstcategory of system information. The remaining SIs in the first categoryof system information of a cell can be broadcasted or provided on demandby another cell. In the request, UE may include information (e.g., cellID, frequency, cell index, etc.) about the cell for which it isrequesting SI.

FIG. 7 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure.

Referring to FIG. 7, in this method of the present disclosure the UE canacquire the system information as shown in FIG. 7. System information iscategorized into two categories: The first category (also referred asminimum SI or essential SI) comprises of one or more System informationwhich is broadcasted periodically by the cell and/or TRP. The secondcategory (also referred as Other SI) comprises of one or more commonsystem information which is provided to UE on demand or can bebroadcasted periodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The firstcategory of system information includes at least SFN, list of PLMN IDs,Cell ID, cell camping parameters, etc. The second category of systeminformation includes the system information not included in firstcategory. The first category (also referred as minimum SI or essentialSI) of system information is periodically broadcasted by the cell and/orTRP. In operation S710, UE acquires first category (also referred asminimum SI or essential SI) of system information from broadcastedinformation.

Network signals in first category of system information i.e. in MinimumSI or essential SI whether the system information in the second categoryis periodically broadcasted or provided on demand. For example, in caseof heterogeneous network comprises of macro cell and small cells, macrocell may indicate that system information is broadcasted whereas smallcells may indicate that system information is not broadcasted. Inanother example, if there are several requests for system informationprovided on demand then network may start to broadcast the systeminformation instead of providing on demand. Minimum SI or essential SImay include in indication which indicates that all SIs of secondcategory of system information are periodically broadcasted or areprovided on demand. Alternately, minimum SI or essential SI may includea separate indication for each SI (e.g. SIB) or set of SIs (i.e., SIBs)wherein each indication indicates whether the associated SI or set ofSIs are periodically broadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI message wherein each SI message carries one ormore SIs (i.e., SIBs). The indication associated with an SI messageindicates whether SIs associated with that SI message are broadcasted orprovided on demand. Mapping of SI message to SIBs in included in minimumSI or essential SI. In order to acquire a SI of second category, UEfirst determines whether that SI is periodically broadcasted or providedon demand. UE determines this based on indication included in firstcategory (also referred as minimum SI or essential SI) of systeminformation.

If first category (also referred as minimum SI or essential SI) ofsystem information indicates that SI which UE wants to acquire isperiodically broadcasted (or not provided on demand) then UE acquiresthe SI from the periodic broadcast using the scheduling informationincluded in first category (also referred as minimum SI or essential SI)of system information. If first category (also referred as minimum SI oressential SI) of system information indicates that SI which UE wants toacquire is not periodically broadcasted (or provided on demand) then UEsends request to BS to receive that SI.

The second category of system information may be further classified intocommon system information and non-common system information. Commonsystem information comprises of one or more SIs (i.e., SIBs) which areneeded by every UE irrespective of feature or service in which they areinterested. Non common system information comprises of one or more SIs(i.e. SIBs) which are not needed by every UE. These SIs are feature orservice specific (e.g. SIBs related to D2D, MTC, V2V, V2X, multimediabroadcast/multicast service (MBMS) etc.).

In order to receive the one or more SIs provided on demand, in operationS720, UE transmits random access preamble. PRACH preambles or PRACHopportunities (i.e. time/frequency resources) for obtaining systeminformation can be different from the PRACH preambles or PRACHopportunities for other purposes. PRACH preambles or PRACH opportunitiesfor obtaining system information can be predefined or signaled bynetwork in first category (also referred as minimum SI or essential SI)of system information.

On receiving the random access preamble, in operation S730, BS transmitsa random access response (RAR) and the RAR may include UL grant fortransmitting the system information request message. RAR includes thecommon system information. RAR may also include timing advance and/orback off indicator and or preamble identifier (identifies the PRACHpreamble).

UE validates that RAR corresponds to PRACH transmitted by it. If thevalidation is successful, in operation S740, UE may transmit SI requestmessage in the UL grant to request one or more system informationaccording to its need. SI request message indicates system informationor set of system information or service or UE type. UE may transmit itsUE ID (i.e., S-TMSI, C-RNTI, RA-RNTI, etc.) along with SI requestmessage. In response to SI request, ENB transmits SI-response whereinthe SI-response includes the requested system information, in operationS750.

Scheduling control information indicating the SI-response can be maskedwith UE's ID (e.g., C-RNTI, RA-RNTI) or a pre-defined ID (e.g.,SI-RNTI). Pre-defined ID can be different for different systeminformation or system information set or service or UE type. UE canindicate the needed system information in SI-Request using the optionsexplained in description of method 1.

In an embodiment, based on PRACH preamble, content of RAR can be one ofthe following:

1. Common system information and No UL grant: This is the case when UEneeds only common SI.

2. Common system information and UL grant: This is the case when UEneeds both common SI and some other SIs. This is also the case when UEneeds common SI and wants to send some other RRC message (e.g.,connection request, connection resume request, etc.) after receiving theRAR.

3. UL grant: This is the case when UE does not need any SI or when UEdoes not need common system information but needs some other SI.

PRACH preamble(s) and/or PRACH opportunity(s) can be different for eachof the above. PRACH preambles or PRACH opportunities for obtainingsystem information for each of these cases can be predefined or signaledby network in first category (also referred as minimum SI or essentialSI) of system information.

UE select the appropriate PRACH preamble and/or PRACH opportunityaccordingly. For example, UE may only need common system information. IfUE needs only common system information it indicates to eNB using theappropriate PRACH preamble and/or PRACH opportunity. PRACH preamble(s)and/or PRACH opportunity(s) for this purpose is different from otherpurposes. In this case, UE will not send SI request after receiving theRAR.

In another scenario, UE needs common system information and also wantsto request additional system information. In this case, UE needs commonsystem information and UL grant in RAR. UE indicates to eNB using theappropriate PRACH preamble and/or PRACH opportunity. PRACH preamble(s)and/or PRACH opportunity(s) for this purpose is different from otherpurposes. In this case, UE will send SI request after receiving the RAR.In another scenario, UE may want to request system information and needsUL grant in RAR. UE indicates to eNB using the appropriate PRACHpreamble and/or PRACH opportunity. PRACH preamble(s) and/or PRACHopportunity(s) for this purpose is different from other purposes.

In an embodiment, eNB may provide the requested system information forone or more cells and/or TRPs. ENB may indicate the cells and/or TRPsfor which system information provided in SI response is applicable. As aresult, the UE does not need to request for system information when theUE changes cell and/or TRP. After the cell and/or TRP change, if the UEdoes not have system information for the new cell and/or TRP then UErequest for system information.

In another embodiment of the present disclosure, BS can indicatesupported SI(s) in essential system information. UE can then request oneor more of the supported SIs using the method (FIG. 7) explainedearlier.

In another embodiment, a cell may broadcast some of the SIs in the firstcategory of system information. The remaining SIs in the first categoryof system information of a cell can be broadcasted or provided on demandby another cell. In the request, UE may include information (e.g., cellID, frequency, cell index, etc.) about the cell for which it isrequesting SI.

FIG. 8 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure.

Referring to FIG. 8, in this method of the present disclosure the UE canacquire the system information as shown in FIG. 8. System information iscategorized into two categories: The first category (also referred asminimum SI or essential SI) comprises of one or more System informationwhich is broadcasted periodically by the cell and/or TRP. The secondcategory (also referred as Other SI) comprises of one or more commonsystem information which is provided to UE on demand or can bebroadcasted periodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The firstcategory of system information includes at least SFN, list of PLMN IDs,Cell ID, cell camping parameters, etc. The second category of systeminformation includes the system information not included in firstcategory.

The first category (also referred as minimum SI or essential SI) ofsystem information is periodically broadcasted by the cell and/or TRP.In operation S810, UE acquires first category (also referred as minimumSI or essential SI) of system information from broadcasted information.

Network signals in first category of system information i.e. in MinimumSI or essential SI whether the system information in the second categoryis periodically broadcasted or provided on demand. For example, in caseof heterogeneous network comprises of macro cell and small cells, macrocell may indicate that system information is broadcasted whereas smallcells may indicate that system information is not broadcasted. Inanother example, if there are several requests for system informationprovided on demand then network may start to broadcast the systeminformation instead of providing on demand. Minimum SI or essential SImay include in indication which indicates that SIs of second category ofsystem information are periodically broadcasted or are provided ondemand. Alternately, minimum SI or essential SI may include a separateindication for each SI (e.g. SIB) or set of SIs (i.e., SIBs) whereineach indication indicates whether the associated SI or set of SIs areperiodically broadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI message wherein each SI message carries one ormore SIs (i.e., SIBs). The indication associated with an SI messageindicates whether SIs associated with that SI message are broadcasted orprovided on demand. Mapping of SI message to SIBs in included in minimumSI or essential SI. In order to acquire a SI of second category, UEfirst determines whether that SI is periodically broadcasted or providedon demand. UE determines this based on indication included in firstcategory (also referred as minimum SI or essential SI) of systeminformation.

If first category (also referred as minimum SI or essential SI) ofsystem information indicates that SI which UE wants to acquire isperiodically broadcasted (or not provided on demand) then UE acquiresthe SI from the periodic broadcast using the scheduling informationincluded in first category (also referred as minimum SI or essential SI)of system information. If first category (also referred as minimum SI oressential SI) of system information indicates that SI which UE wants toacquire is not periodically broadcasted (or provided on demand) then UEsends request to BS to receive that SI.

In order to receive the one or more system information provided ondemand, in operation S820, UE transmits random access preamble (PRACH).PRACH preambles and/or or PRACH opportunities for obtaining systeminformation in RAR can be different from the PRACH preambles and/orPRACH opportunities for other purposes.

In an embodiment of the present disclosure, on receiving the randomaccess preamble, in operation S830, BS transmits a RAR. The randomaccess preamble acts as SI request in this method. RAR includes SIresponse i.e. the common system information.

In an embodiment, UE may obtain other system information specific to itsneed using dedicated signaling (For example, UE may enter connectedstate and request system information in dedicated manner to eNB). Inalternate embodiment, on receiving the random access preamble for SI, SIresponse can be broadcasted or provided in unicast manner. Schedulingcontrol information indicating the SI-response can be masked with UE'sID (e.g., C-RNTI, RA-RNTI) or a pre-defined ID (e.g. SI-RNTI).Pre-defined ID can be different for different system information orsystem information set or service or UE type. One or more SIs (i.e.SIBs) requested by UE are provided within some time window (i.e., SIResponse Window) after sending the SI request. After sending the SIrequest, the UE listens to NR-PDCCH in SI Response Window for receivingthe requested SIBs.

If UE does not receive the requested SIBs within the SI Response Windowthen UE may retransmit the SI request. The length of SI response windowis provided in minimum SI or essential SI. Alternately, after sendingthe SI request, for receiving the requested SIB, UE monitors the SIwindow of requested SIB in one or more SI periods of that SIB.

The scheduling information for other SI including SIB type, validityinformation, periodicity, SI-window information can be provided inminimum SI irrespective of whether Other SI is periodically broadcastedor provided on demand. In one embodiment, UE first checks for SIresponse in SI response window and if not received it monitors the SIwindow for receiving the requested SIs.

In an embodiment in which SI response is broadcasted in SI windowinstead of SI response window or in RAR, RAR may still be transmitted toacknowledge the successful reception of SI request. In an embodiment inwhich SI response is broadcasted in SI window instead of SI responsewindow or in RAR, successful reception of SI request can be indicated byBS by including an indication in minimum SI.

In an embodiment, eNB may provide the system information for one or morecells and/or TRPs. ENB may indicate the cells and/or TRPs for whichsystem information provided in RAR is applicable. As a result, the UEdoes not need to request for system information when the UE changes celland/or TRP. After the cell and/or TRP change, if the UE does not havesystem information for the new cell and/or TRP then UE request forsystem information.

In another embodiment of the present disclosure, BS can indicatesupported SI(s) in essential system information. UE can then request oneor more of the supported SIs using the method (FIG. 8) explainedearlier.

FIG. 9 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure.

Referring to FIG. 9, in this method of the present disclosure the UE canacquire the system information as shown in FIG. 9. System information iscategorized into two categories: The first category (also referred asminimum SI or essential SI) comprises of one or more System informationwhich is broadcasted periodically by the cell and/or TRP. The secondcategory (also referred as Other SI) comprises of one or more commonsystem information which is provided to UE on demand or can bebroadcasted periodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The firstcategory of system information includes at least SFN, list of PLMN IDs,Cell ID, cell camping parameters, etc. The second category of systeminformation includes the system information not included in firstcategory.

The first category (also referred as minimum SI or essential SI) ofsystem information is periodically broadcasted by the cell and/or TRP.In operation S910, UE acquires first category (also referred as minimumSI or essential SI) of system information from broadcasted information.

Network signals in first category of system information i.e. in MinimumSI or essential SI whether the system information in the second categoryis periodically broadcasted or provided on demand. For example, in caseof heterogeneous network comprises of macro cell and small cells, macrocell may indicate that system information is broadcasted whereas smallcells may indicate that system information is not broadcasted.

In another example, if there are several requests for system informationprovided on demand then network may start to broadcast the systeminformation instead of providing on demand. Minimum SI or essential SImay include in indication which indicates that SIs of second category ofsystem information are periodically broadcasted or are provided ondemand. Alternately, minimum SI or essential SI may include a separateindication for each SI (e.g. SIB) or set of SIs (i.e., SIBs) whereineach indication indicates whether the associated SI or set of SIs areperiodically broadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI message wherein each SI message carries one ormore SIs (i.e., SIBs). The indication associated with an SI messageindicates whether SIs associated with that SI message are broadcasted orprovided on demand. Mapping of SI message to SIBs in included in minimumSI or essential SI. In order to acquire a SI of second category, UEfirst determines whether that SI is periodically broadcasted or providedon demand.

UE determines this based on indication included in first category (alsoreferred as minimum SI or essential SI) of system information. If firstcategory (also referred as minimum SI or essential SI) of systeminformation indicates that SI which UE wants to acquire is periodicallybroadcasted (or not provided on demand) then UE acquires the SI from theperiodic broadcast using the scheduling information included in firstcategory (also referred as minimum SI or essential SI). If firstcategory (also referred as minimum SI or essential SI) of systeminformation indicates that SI which UE wants to acquire is notperiodically broadcasted (or provided on demand) then UE sends requestto BS to receive that SI.

In order to receive one or more system information provided on demand,in operation S920, UE sends random access preamble (PRACH-SI). Therandom access preamble acts as SI request in this method. PRACHpreambles and/or or PRACH opportunities for obtaining system informationin RAR can be different from the PRACH preambles and/or PRACHopportunities for other purposes.

In an embodiment, PRACH-SI preamble for obtaining system information inRAR is pre-defined. In this option, PRACH time/frequency resource can beone of following:

Alt1: Fixed relative to PSS/SSS/BCH/SFN 0

Alt2: Provided in essential system information

Alt3: Use normal PRACH time/frequency resource

In another embodiment, PRACH-SI preamble for obtaining systeminformation in RAR is not pre-defined. UE can use any PRACH preamble. Inthis option, PRACH time/frequency resource is specific to PRACH-SI andcan be one of the following:

Alt1: Fixed relative to PSS/SSS/BCH/SFN 0

Alt2: Provided in essential system information

UE determines the PRACH-SI Transmit Power using one of the followingoptions:

Alt1: Open loop power control similar to PRACH

Alt2: Transmit at max power

Alt3: Transmit power is configured

On receiving the PRACH-SI, in operation S930, BS transmits a RAR. RARincludes the other system information. In alternate embodiment, onreceiving the random access preamble for SI, SI response can bebroadcasted or provided in unicast manner. Scheduling controlinformation indicating the SI-response can be masked with UE's ID (e.g.,C-RNTI, RA-RNTI) or a pre-defined ID (e.g., SI-RNTI). Pre-defined ID canbe different for different system information or system information setor service or UE type.

One or more SIs (i.e., SIBs) requested by UE are provided within sometime window (i.e., SI Response Window) after sending the SI request.After sending the SI request, the UE listens to NR-PDCCH in SI ResponseWindow for receiving the requested SIBs. If UE does not receive therequested SIBs within the SI Response Window then UE may retransmit theSI request. The length of SI response window is provided in minimum SIor essential SI.

Alternately, after sending the SI request, for receiving the requestedSIB, UE monitors the SI window of requested SIB in one or more SIperiods of that SIB. The scheduling information for other SI includingSIB type, validity information, periodicity, SI-window information canbe provided in minimum SI irrespective of whether Other SI isperiodically broadcasted or provided on demand. In one embodiment, UEfirst checks for SI response in SI response window and if not receivedit monitors the SI window for receiving the requested SIs. In anembodiment in which SI response is broadcasted in SI window instead ofSI response window or in RAR, RAR may still be transmitted toacknowledge the successful reception of SI request.

In an embodiment in which SI response is broadcasted in SI windowinstead of SI response window or in RAR, successful reception of SIrequest can be indicated by BS by including an indication in minimum SI.

In an embodiment, eNB may provide the requested system information forone or more cells. ENB may indicate the cells for which systeminformation provided is applicable. As a result, the UE does not need torequest for system information when the UE changes cell. After the cellchange, if the UE does not have system information for the new cell thenUE request for system information.

In another embodiment of the present disclosure, BS can indicatesupported SI(s) in essential system information. UE can then request oneor more of the supported SIs using the method (FIG. 9) explainedearlier.

FIG. 10 illustrates a method for indicating in broadcasted essentialsystem information whether other system information is broadcasted ornot according to an embodiment of the present disclosure.

Referring to FIG. 10, in an embodiment of the present disclosure systeminformation (other than essential system information) can also bebroadcasted by the BS. BS may indicate in broadcasted essential systeminformation whether other system information is broadcasted or not asshown in FIG. 10. If not broadcasted then UE can request using themethod (FIG. 9) explained earlier.

In operation S1010, BS broadcasts minimum/essential system information(e.g., set SI_TX_Indication to zero) periodically. In operation S1020and S1030, UE transmits PRACH-SI to obtain other system information asthe SI_TX_Indication is set to zero. In operation S1040, BS transmitsSI-Response/RAR-SI including other system information in response to thePRACH-SI.

In operation S1050, BS broadcasts minimum/essential system information(e.g., set SI_TX_Indication to one) periodically. In operation S1060 andS1070, UE obtains other system information from broadcast signaling asthe SI_TX_Indication is set to one.

If broadcasted then UE read broadcasted system information to acquirethe required system information. In case of heterogeneous networkcomprises of macro cell and small cells, macro cell may indicate thatsystem information is broadcasted (e.g., set SI_TX_Indication to one)whereas small cells may indicate that system information is notbroadcasted (e.g., set SI_TX_Indication to zero).

In an embodiment, SI_TX_Indication can be signaled for each SI or Set ofSIs in minimum/essential system information.

In an embodiment, BS may provide the requested system information forone or more cells. ENB may indicate the cells for which systeminformation provided in RAR-SI is applicable. As a result, the UE doesnot need to request for system information when the UE changes cell.After the cell change, if the UE does not have system information forthe new cell then UE request for system information.

FIG. 11 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure.

Referring to FIG. 11, in this method of the present disclosure the UEcan acquire the system information as shown in FIG. 11. Systeminformation is categorized into two categories: The first category (alsoreferred as minimum SI or essential SI) comprises of one or more Systeminformation which is broadcasted periodically by the cell and/or TRP.The second category (also referred as Other SI) comprises of one or morecommon system information which is provided to UE on demand or can bebroadcasted periodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The secondcategory of system information includes the system information notincluded in first category.

The first category (also referred as minimum SI or essential SI) ofsystem information is periodically broadcasted by the cell and/or TRP.In operation S1110, UE acquires first category (also referred as minimumSI or essential SI) of system information from broadcasted information.

Network signals in first category of system information i.e. in MinimumSI or essential SI whether the system information in the second categoryis periodically broadcasted or provided on demand. For example, in caseof heterogeneous network comprises of macro cell and small cells, macrocell may indicate that system information is broadcasted whereas smallcells may indicate that system information is not broadcasted.

In another example, if there are several requests for system informationprovided on demand then network may start to broadcast the systeminformation instead of providing on demand. Minimum SI or essential SImay include in indication which indicates that SIs of second category ofsystem information are periodically broadcasted or are provided ondemand. Alternately, minimum SI or essential SI may include a separateindication for each SI (e.g. SIB) or set of SIs (i.e., SIBs) whereineach indication indicates whether the associated SI or set of SIs areperiodically broadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI message wherein each SI message carries one ormore SIs (i.e., SIBs). The indication associated with an SI messageindicates whether SIs associated with that SI message are broadcasted orprovided on demand. Mapping of SI message to SIBs in included in minimumSI or essential SI. In order to acquire a SI of second category, UEfirst determines whether that SI is periodically broadcasted or providedon demand.

UE determines this based on indication included in first category (alsoreferred as minimum SI or essential SI) of system information. If firstcategory (also referred as minimum SI or essential SI) of systeminformation indicates that SI which UE wants to acquire is periodicallybroadcasted (or not provided on demand) then UE acquires the SI from theperiodic broadcast using the scheduling information included in firstcategory (also referred as minimum SI or essential SI). If firstcategory (also referred as minimum SI or essential SI) of systeminformation indicates that SI which UE wants to acquire is notperiodically broadcasted (or provided on demand) then UE sends requestto BS to receive that SI.

In order to receive the other system information, in operation S1120, UEsends random access preamble (PRACH-SI). The random access preamble actsas SI request in this method. PRACH preambles and/or or PRACHopportunities for obtaining system information in RAR can be differentfrom the PRACH preambles and/or PRACH opportunities for other purposes.

PRACH preambles and/or or PRACH opportunities for each SI (i.e., SIB) orset of SIs (i.e., SIBs) can be pre-defined or signaled in first category(also referred as minimum SI or essential SI). In one embodiment,PRACH-SI preamble for obtaining system information in RAR ispre-defined.

PRACH-SI preamble can be specific to system information or a set ofsystem information or service of UE type. In this option, PRACHtime/frequency resource can be one of following:

Alt1: Fixed relative to PSS/SSS/BCH/SFN 0

Alt2: Provided in essential system information. This can be specific tosystem information or a set of system information or service or UE type.

Alt3: Use PRACH time/frequency resource

In another embodiment, PRACH-SI preamble for obtaining systeminformation in RAR is not pre-defined. UE can use any PRACH preamble. Inthis option, PRACH time/frequency resource is specific to PRACH-SI andcan be one of the following:

Alt1: Fixed relative to PSS/SSS/BCH/SFN 0

Alt2: Provided in essential system information. This can be specific tosystem information or a set of system information or service or UE type.

UE determines the PRACH-SI Transmit Power using one of the followingoptions:

Alt1: Open loop power control similar to PRACH

Alt2: Transmit at max power

Alt3: Transmit power is configured

On receiving the PRACH-SI, in operation S1130, BS transmits a RAR. RARincludes the requested system information. In alternate embodiment, onreceiving the random access preamble for SI, SI response can bebroadcasted or provided in unicast manner. Scheduling controlinformation indicating the SI-response can be masked with UE's ID (e.g.,C-RNTI, RA-RNTI) or a pre-defined ID (e.g., SI-RNTI). Pre-defined ID canbe different for different system information or system information setor service or UE type.

One or more SIs (i.e. SIBs) requested by UE are provided within sometime window (i.e. SI Response Window) after sending the SI request.After sending the SI request, the UE listens to NR-PDCCH in SI ResponseWindow for receiving the requested SIBs. If UE does not receive therequested SIBs within the SI Response Window then UE may retransmit theSI request. The length of SI response window is provided in minimum SIor essential SI.

Alternately, after sending the SI request, for receiving the requestedSIB, UE monitors the SI window of requested SIB in one or more SIperiods of that SIB. The scheduling information for other SI includingSIB type, validity information, periodicity, SI-window information canbe provided in minimum SI irrespective of whether Other SI isperiodically broadcasted or provided on demand. In one embodiment, UEfirst checks for SI response in SI response window and if not receivedit monitors the SI window for receiving the requested SIs.

In an embodiment in which SI response is broadcasted in SI windowinstead of SI response window or in RAR, RAR may still be transmitted toacknowledge the successful reception of SI request. In an embodiment inwhich SI response is broadcasted in SI window instead of SI responsewindow or in RAR, successful reception of SI request can be indicated byBS by including an indication in minimum SI.

FIG. 12 illustrates a method for indicating in broadcasted essentialsystem information whether other system information is broadcasted ornot according to another embodiment of the present disclosure.

Referring to FIG. 12, in another embodiment of the present disclosuresystem information (other than essential system information) can also bebroadcasted by the BS. BS may indicate in broadcasted essential systeminformation whether other system information is broadcasted or not asshown in FIG. 12.

In operation S1210, BS broadcasts minimum/essential system information(e.g. set SI_TX_Indication to zero) periodically. In one embodiment,indication can be there specific to SI or set of Sis or service(indication to request for system information or indication that systeminformation is broadcasted).

In operation S1220 and S1230, in response to the SI_TX_Indication, UEtransmits SI Request/PRACH-SI to obtain other system information. SIRequest/PRACH-SI is specific to SI or set of Sis or service. Inoperation S1240, BS transmits SI-Response/RAR-SI including requestedsystem information in response to the PRACH-SI.

If system information is not broadcasted then UE can request using themethod (FIG. 11) explained earlier. If broadcasted then UE readbroadcasted system information to acquire the required systeminformation. In case PRACH-SI information is broadcasted for on demandsignaling i.e. for requesting system information, absence of thisinformation in broadcasted essential system information may indicatethat UE can read system information from broadcast signaling. In case ofheterogeneous network comprises of macro cell and small cells, macrocell may indicate that system information is broadcasted (e.g., setSI_TX_Indication to one) whereas small cells may indicate that systeminformation is not broadcasted (e.g., set SI_TX_Indication to zero).

In one embodiment, eNB may provide the requested system information forone or more cells. ENB may indicate the cells for which systeminformation provided is applicable. As a result, the UE does not need torequest for system information when the UE changes cell. After the cellchange, if the UE does not have system information for the new cell thenUE request for system information.

In another embodiment of the present disclosure, BS can also indicatesupported SI(s) in essential system information. UE can then request oneor more of the supported SIs using the method (FIG. 1) explainedearlier.

FIG. 13 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure.

Referring to FIG. 13, in this method of the present disclosure the UEcan acquire the system information as shown in FIG. 13. Systeminformation is categorized into two categories: The first category (alsoreferred as minimum SI or essential SI) comprises of one or more Systeminformation which is broadcasted periodically by the cell and/or TRP.The second category (also referred as Other SI) comprises of one or morecommon system information which is provided to UE on demand or can bebroadcasted periodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The secondcategory of system information includes the system information notincluded in first category.

In this method BS broadcasts the first category (also referred asminimum SI or essential SI) of system information. In operation S1310,UE acquires first category (also referred as minimum SI or essential SI)of system information from broadcasted information.

Network signals in first category of system information, i.e., inMinimum SI or essential SI whether the system information in the secondcategory, is periodically broadcasted or provided on demand. Forexample, in case of heterogeneous network comprises of macro cell andsmall cells, macro cell may indicate that system information isbroadcasted whereas small cells may indicate that system information isnot broadcasted.

In another example, if there are several requests for system informationprovided on demand then network may start to broadcast the systeminformation instead of providing on demand. Minimum SI or essential SImay include in indication which indicates that all SIs of secondcategory of system information are periodically broadcasted or areprovided on demand. Alternately, minimum SI or essential SI may includea separate indication for each SI (e.g., SIB) or set of SIs (i.e. SIBs)wherein each indication indicates whether the associated SI or set ofSIs are periodically broadcasted or are provided on demand.

Alternately, minimum SI or essential SI may include a separateindication for each SI message wherein each SI message carries one ormore SIs (i.e., SIBs). The indication associated with an SI messageindicates whether SIs associated with that SI message are broadcasted orprovided on demand. Mapping of SI message to SIBs in included in minimumSI or essential SI. In order to acquire a SI of second category, UEfirst determines whether that SI is periodically broadcasted or providedon demand. UE determines this based on indication included in firstcategory (also referred as minimum SI or essential SI) of systeminformation. If first category (also referred as minimum SI or essentialSI) of system information indicates that SI which UE wants to acquire isperiodically broadcasted (or not provided on demand) then UE acquiresthe SI from the periodic broadcast using the scheduling informationincluded in first category (also referred as minimum SI or essentialSI).

If first category (also referred as minimum SI or essential SI) ofsystem information indicates that SI which UE wants to acquire is notperiodically broadcasted (or provided on demand) then UE sends requestto BS to receive that SI, in operation S1320. Optionally, the BS maytransmit the SI in a RAR message, in operation S1330.

In this method, BS also broadcasts the scheduling information about theother system information. However, other system information is notperiodically broadcasted. BS broadcasts the other system information fordefined time duration on receiving a trigger (e.g., PRACH-SI) from theUE, in operations S1340 and S1350. The trigger can be specific to asystem information or set of system information or service or UE type.During the time when the system information is broadcasted afterreceiving a trigger from UE, BS may broadcasts an indication that it isbroadcasting the system information. The indication can be specific tosystem information or a set of system information or service or UE type.This ensures that other UEs does not trigger PRACH-SI and reads thesystem information from broadcast. The trigger to broadcast can betransmitted at time slots configured by network. In one embodiment,trigger to broadcast can be transmitted at a time relative to locationof particular system information. In operation S1360, the BS broadcastsand the UE acquires essential SI. In operation S1370, the BS broadcastsand the UE acquires the SI, a location of SI may be indicated in theessential SI.

FIG. 14 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure. In this method of thepresent disclosure, the UE can acquire the system information as shownin FIG. 14.

Referring to FIG. 14, in this method of the present disclosure the UEcan acquire the system information as shown in FIG. 14. Systeminformation is categorized into two categories: The first category (alsoreferred as minimum SI or essential SI) comprises of one or more Systeminformation which is broadcasted periodically by the cell and/or TRP.The second category (also referred as Other SI) comprises of one or morecommon system information which is provided to UE on demand or can bebroadcasted periodically.

The first category comprises of essential system information such asinformation required for initial access to a cell, information requiredfor acquiring the system information in second category. The secondcategory of system information includes the system information notincluded in first category. In this method BS broadcasts the firstcategory (also referred as minimum SI or essential SI) of systeminformation. In operation S1410, UE acquires first category (alsoreferred as minimum SI or essential SI) of system information frombroadcasted information.

Network signals in first category of system information i.e. in MinimumSI or essential SI whether the system information in the second categoryis periodically broadcasted or provided on demand. For example, in caseof heterogeneous network comprises of macro cell and small cells, macrocell may indicate that system information is broadcasted whereas smallcells may indicate that system information is not broadcasted. Inanother example, if there are several requests for system informationprovided on demand then network may start to broadcast the systeminformation instead of providing on demand.

Minimum SI or essential SI may include in indication which indicatesthat SIs of second category of system information are periodicallybroadcasted or are provided on demand. Alternately, minimum SI oressential SI may include a separate indication for each SI (e.g., SIB)or set of SIs (i.e., SIBs) wherein each indication indicates whether theassociated SI or set of SIs are periodically broadcasted or are providedon demand. Alternately, minimum SI or essential SI may include aseparate indication for each SI message wherein each SI message carriesone or more SIs (i.e., SIBs). The indication associated with an SImessage indicates whether SIs associated with that SI message arebroadcasted or provided on demand. Mapping of SI message to SIBs inincluded in minimum SI or essential SI.

In order to acquire a SI of second category, UE first determines whetherthat SI is periodically broadcasted or provided on demand. UE determinesthis based on indication included in first category (also referred asminimum SI or essential SI) of system information. If first category(also referred as minimum SI or essential SI) of system informationindicates that SI which UE wants to acquire is periodically broadcasted(or not provided on demand) then UE acquires the SI from the periodicbroadcast using the scheduling information included in first category(also referred as minimum SI or essential SI). If first category (alsoreferred as minimum SI or essential SI) of system information indicatesthat SI which UE wants to acquire is not periodically broadcasted (orprovided on demand) then UE sends request to BS to receive that SI.

To acquire the one or more SIs provided on demand, in operation S1420,UE performs RRC connection setup procedure if UE is in RRC idle state.In RRC connected state, in operation S1430, UE sends SI request message.SI request message indicates one or more system information which UEneeds or indicates one or more set of system information which UE needsor indicates service (e.g., eMBB, MTC, URLL, etc.) for which UE needssystem information or UE type. UE may transmit its UE ID (i.e., S-TMSI,C-RNTI, RA-RNTI, etc.) along with SI request message.

In response to SI request, in operation S1440, BS transmits SI-responsewherein the SI-response includes the requested system information.Scheduling control information indicating the SI-response can be maskedwith UE's ID (e.g., C-RNTI, RA-RNTI) or a pre-defined ID (e.g.,SI-RNTI). Pre-defined ID can be different for different systeminformation or system information set or service or UE type.

UE can indicate the needed system information in SI-Request using themechanisms explained in method 1.

In one embodiment SI request can be included in RRC connection requestand SI response can be included RRC connection response. In anotherembodiment, BS can determine the system information needed by UE basedon service supported by UE or based on service for which UE hasrequested connection and provide the system information to UE usingdedicated signaling.

In an embodiment, eNB may provide the requested system information forone or more cells. ENB may indicate the cells for which systeminformation provided in SI response is applicable. As a result, the UEdoes not need to request for system information when the UE changescell. After the cell change, if the UE does not have system informationfor the new cell then UE request for system.

In another embodiment, a cell may broadcast some of the SIs in the firstcategory of system information. The remaining SIs in the first categoryof system information of a cell can be broadcasted or provided on demandby another cell. In the request, UE may include information (e.g., cellID, frequency, cell index, etc.) about the cell for which it isrequesting SI.

FIG. 15 illustrates a method for acquiring system information accordingto the other embodiment of the present disclosure.

Referring to FIG. 15, in this method of the present disclosure the UEcan acquire the system information as shown in FIG. 15. In operationS1510, BS (or 5G Cell) broadcasts the synchronization signals, i.e.,PSS/SSS. No system information is broadcasted periodically.

In order to request the SI, in operation S1520, UE transmits thePRACH-SI preamble. The PRACH-SI preamble can be pre-defined. The timeand frequency resource for PRACH-SI transmission can be defined relativeto PSS/SSS. On receiving the PRACH-SI preamble, in operation S1530, BSmay broadcast minimum SI or the system information or the common systeminformation. If any system information is not broadcasted then UE mayacquire using the methods explained earlier.

In the methods explained earlier, UE requests for system information ondemand, in the present disclosure network can configure the period atwhich UE can request. This can reduce too many requests.

If the response is broadcasted then it can be in a time window relativeto time in which request is sent. In the methods explained earlier UErequests for system information on demand, UE may monitor broadcasttransmission for a defined time duration to receive the desired systeminformation before requesting the desired system information.

FIG. 16 illustrates a method for providing system information within atime window according to an embodiment of the present disclosure.

Referring to FIG. 16, one or more SIBs requested by UE are providedwithin some time window (i.e., SI Response Window) after sending the SIrequest. After sending the SI request, the UE listens to NR-PDCCH in SIResponse Window for receiving the requested SIBs. If UE does not receivethe requested SIBs within the SI Response Window then UE may retransmitthe SI request.

In an embodiment, the length of SI response window is provided in mobilesubscriber identity (MSI) (essential system information). In anotherembodiment, acknowledgment for SI request may be performed as UE checksfor RAR after sending SI request or UE checks for indication in MSI.

FIG. 17 illustrates a method for providing system information bymonitoring a time window in one or more periods according to anembodiment of the present disclosure.

Referring to FIG. 17, after sending the SI request, for receiving therequested SIB, UE monitors the SI window of requested SIB in one or moreSI periods of that SIB. The scheduling information for other SI includesSIB type, validity information, periodicity, SI-window information inminimum SI irrespective of whether Other SI is periodically broadcastedor provided on demand.

In one embodiment, acknowledgment for SI request may be performed as UEchecks for RAR after sending SI request or UE checks for indication inMSI.

Minimization of SI Re-Acquisition

There can be several small cells in coverage of macro cell. Currentlysystem information is cell specific. Currently each cell (small cell aswell as macro cell) transmits their own system information. In anembodiment of the present disclosure, a first cell (e.g., Macro cell)provides information about one or more second cells (e.g., small cells).

Several system information parameters may have the same values acrossmany cells. So in an embodiment system information parameters can becategorized into cell specific information and non-cell specificinformation. Non cell specific information i.e. system informationhaving common values across one or more second cells (e.g., small cells)in can be signaled using broadcasted or dedicated signaling by firstcell (e.g., macro cell) or can be provided on demand. Cell specificinformation is signaled by each cell.

In an embodiment, a first cell may signal several sets of systeminformation using broadcasted or dedicated signaling. In one embodiment,each of these sets may be indexed in the order in which they aresignaled by first cell. The second cell may indicate (using broadcast ordedicated signaling) which system information set amongst the multiplesets signaled by first cell are applicable to this cell. In alternateembodiment, first cell may indicate list of cell ids of cells along witheach set, wherein cell id identifies the cell for which this set isapplicable.

In embodiment, cell specific system information can be obtained asfollows:

Option 1: UE obtains from Macro Cell

1a: Macro cell broadcasts these information in broadcast signaling.

1b: Macro cell provide these information in dedicated signaling.

Macro cell may indicate using broadcast signaling whether it providessuch information.

Macro cell may also indicate whether it provides such information indedicated signaling if such information is not broadcasted.

On demand signaling as explained earlier can also be used to requestinformation from Macro cell.

Option 2: UE obtains directly from cell

If Macro cell does not provide the information then UE obtains directlyfrom cell.

Small cell may broadcast these information.

On demand signaling as explained earlier can be used to requestinformation from cell.

In the methods explained earlier, the system information received fromperiodic broadcast or using on demand SI request procedure explainedearlier from a cell can be used for one or more cells. The cells forwhich received system information can be used can be indicated by thecell from which system information is obtained either from periodicbroadcast or using on demand SI request procedure explained earlier. UEmay also receive system information from multiple cells from periodicbroadcast or using on demand SI request procedure. As a result, the UEdoes not need to request or reacquire the system information when the UEchanges cell. After the cell change, if the UE does not have systeminformation for the new cell then UE reacquire or request for systeminformation.

FIG. 18 illustrates a method for configuring system information area IDaccording to an embodiment of the present disclosure.

Referring to FIG. 18, in an alternate embodiment, system informationarea concept can be defined. System information area refers to an areacovering one or more cells or transmits point or transmit/receive pointwherein the system information used is same. System information area canbe identified by a system information area identifier. Cell or transmitpoint or transmit/receive point broadcasts the system info areaidentifier.

When a UE moves from one cell to another, it checks the SI Area ID. Ifthere is change in SI Area ID then UE reacquires the system information.For example, as shown in FIG. 18, if UE moves from cell 1 to cell 3, itdoes not need to reacquire the system information. If UE moves from cell1 to cell 8 then it needs to reacquire the system information.

In an embodiment of the present disclosure system information area (orSI Area ID) can be different for different SIs (or SIBs). In anembodiment of the present disclosure system information area (or SI areaID) can be different for different sets of SIs (SIBs). In an embodimentof the present disclosure one system information area (or SI Area ID)can be there for SIs (or SIBs). In an embodiment of the presentdisclosure some SIs are cell specific and SI area ID is not associatedwith them.

In an embodiment of the present disclosure within an SI area, differentversions of associated SI can be used. Each of these versions isidentified by an index or value tag. Let's say SI areas for SIB X are asshown in FIG. 16. Cell 1, Cell 2 and Cell 3 use a configuration of SIBx.Cell 1, Cell 2 and Cell 3 broadcasts that for SIBx, SI area ID is 1 andindex/value tag is P. If cell 1, cell 2 and cell 3 wants to use adifferent configuration for SIBx, then they broadcast that for SIBx, SIarea ID is 1 and index/value tag is Q. Within the same SI area if thereis change in index or value tag, and UE does not have a valid SIconfiguration corresponding to the new index/value tag of that SI area,UE reacquires the corresponding SI. The SI configuration identified byindex/value tag is valid in SI area in which it is obtained. It is notvalid in another SI area. The scope of validity of index/value tag iswithin the SI area. For example, the configuration of SIBx identified byindex/value tag P in SI area ID 1 is not same as configuration of SIBxidentified by index/value tag P in SI area ID 2 or SI area ID 3. It isto be noted that in prior art the scope of valueTag is one cell. In thismethod of the present disclosure scope of valueTag is SI area i.e.multiple cells.

FIG. 19 illustrates a method for indexing system information parametersaccording to an embodiment of the present disclosure.

Referring to FIG. 19, in an embodiment of the present disclosure, BS maysupport multiple configuration sets of values for system informationparameters. For example, let's say SI comprises of parameters P, Q andR. Let's says parameter P can have values P0, P1. Parameter Q can havevalues Q0, Q1, Q2. Parameter R can have values R0, R1. There can be2*3*2=12 possible configurations for these parameters wherein eachconfiguration has at least one parameter's value different from otherconfiguration. Each of these configurations is given an index. Insteadof signaling (either in broadcast or dedicated signaling) the parametersand there values, index can be signaled. For example configuration 0:P->P0, Q->Q0, R->R0; Configuration 1: P->P0, Q->Q1, R->R0; and so on.

For SI having parameters A, B and C possible configuration sets areshown in FIG. 19. In the example, Parameter A can have two possiblevalues A0 and A1. Parameter B can have two possible values B0 and B1.Parameter C can have two possible values C0 and C1. Note that eachparameter can have different number of values. Each Path from top tobottom in tree (FIG. 16) is one valid configuration. Theseconfigurations can be sequentially numbered as shown in FIG. 16. 8possible configurations are as follows:

Idx0: {A0, B0, C0}, Idx1: {A0, B0, C1}; Idx2: {A0, B1, C0}, Idx3: {A0,B1, C1}; Idx4: {A1, B0, C0}, Idx5: {A1, B0, C1}; Idx6: {A1, B1, C0},Idx7: {A1, B1, C1}; idx={index of value of parameter A*(number of valuesof B*number of values of C)}+{index of value of parameter B*(number ofvalues of C)}+index of value of parameter C. In order to allow skippingof a parameter in a configuration, skipping can be considered asadditional value. For example, if parameter A can be skipped thenParameter A can have three values A0, A1, skip. A0 value has index 0, A1value has index 1 and skip value has index 2.

If a possible value of each SI parameter is known, and then given theindex, configuration can be known corresponding to that index. SI can becategorized into various parts/groups etc. wherein each part or grouphas his own configuration indexes. Each SI part or SI group can haveseveral configurations and each configuration can be indicated usingindex as illustrated above. For example, let's say there are two SIparts, SI part 1 and SI part 2. SI part 1 has three parameters A, B, C.SI part has two parameters P, Q. SI part 1 configuration and SI part 2configuration can be indicated independently using their ownconfiguration indexes.

Configuration index can be broadcasted or signaled using dedicatedsignaling. If SI is requested on demand then configuration index can besignaled instead of full configuration in response. Alternately,configuration index for SI can be broadcasted. If UE cannot knowconfiguration based on broadcasted index then it can request BS/eNB/TRPto provide configuration corresponding to index by sending the index inSI request. UE may not know configuration based on index if it does notknow the values of parameters which are supported in Cell/BS/eNB/TRP.For example, parameter A can have values A0, A1, A2, and A3. But valuesA0, A1 may be supported in cell 1 whereas values A2, A3, A1 may besupported in another cell 2. If UE cannot know configuration based onbroadcasted index then it can request BS/eNB/TRP to provide values ofparameters of SI supported in Cell/BS/eNB/TRP in SI request. Once thevalues of parameters of SI supported in Cell/BS/eNB/TRP are known, UEcan determine the configuration corresponding to broadcast index. SIrequest/response can be signaled using method 1 to 9 explained earlier.

The supported values of parameters of SI can be same throughout thenetwork or can be specific to cell/TRP. The supported values ofparameters of SI part/group can be same throughout the network and forother SI part/group it can be specific to cell/TRP.

In another embodiment, instead of indexing as shown in FIG. 19, networkor cell/TRP/eNB can maintain several configurations for SI or SI part orSI group and assign a distinct index/identifier to each configuration.Network indicates the index/identifier in broadcast signaling for eachSI or SI part/group. UE first receives the broadcast signaling and getsthe index/identifier for a SI or SI part/group. If UE does not haveconfiguration corresponding to index/identifier UE request theconfiguration corresponding to index/identifier using on demandsignaling explained earlier. Index/identifier can be included inrequest. If UE has valid configuration corresponding to index/identifierthen UE uses it and does not need to request. Note that in oneembodiment, this index/identifier can be valid across cells or TRPs oreNBs for an SI or SI part of SI group. In another embodiment, thisindex/identifier can be valid across TRPs of same cell for an SI or SIpart of SI group. Whether the index/identifier for an SI or SI part orSI group is valid across cells or TRPs or eNBs etc. can be pre-definedor indicated in broadcast signaling. UE can store the configurationcorresponding to an index/identifier for a defined life time.

FIG. 20 illustrates a method for configuring system informationconfiguration ID according to an embodiment of the present disclosure.

Referring to FIG. 20, when a UE moves from one cell to another cell, ifthere is change in index for a SIB and it does not have theconfiguration corresponding to index used in that cell, UE reacquiresthe SI otherwise not. Let's say for SIB X network uses threeconfigurations identified by index X, Y, Z as shown in FIG. 18. If UEmoves from cell 1 to cell 3, it does not needs to reacquire SIBx, asboth cells uses same configuration. If UE moves from cell 1 to cell 2,it has to reacquire SIBx if it does not have a stored configurationcorresponding to index x. Unlike the previous method, scope of index isentire network instead of SI area. The index can also be named asvalueTag wherein the scope of valueTag is entire network instead of onecell.

System Information Update Procedure

UE can be notified about the system information update in one of thefollowing ways:

Option 1

System information is categorized into various parts/groups/sets. BSbroadcasts System Information Set(s) supported. BS also broadcastsValueTag/identifier/configuration index for each supported systeminformation set/part/group. Change in value tag/identifier/configurationindex corresponding to a system information set indicates that systeminformation set/group/part is updated. Additionally BS may alsobroadcast change notification for each system information of a service.OR

BS broadcasts Service(s) supported. BS also broadcastsvalueTag/identifier/configuration index for each supported service.Change in value tag/identifier/configuration index corresponding toservice indicates that system information for that service is updated.Additionally BS may also broadcast change notification for each systeminformation of a service.

Option 2

Change notification for each supported system information set or serviceis indicated in paging message. ValueTag/identifier/configuration indexassociated with updated system information can also be indicated inpaging message.

Option 3

Change notification can be indicated using a SI Update message

Each SI update message can indicate notification for a group of SI(s).RNTI specific to group can be used to schedule the SI update message.

SI update message can be RRC message or DCI signaled in PDCCH.

Obtaining Updated Information

UE request updated system information set or service specific systeminformation if the update indication is received using the methodsexplained earlier (i.e. broadcast or on demand). If the systeminformation set changed is part of broadcasted information then UEobtains updated system information from broadcast. If the systeminformation set changed is part of on demand system information then UEobtains updated system information using on demand signaling.

Alt: network (NW) may broadcast the updated information for defined timeperiod. UE reads broadcasted information.

In an embodiment, ValueTag/identifier/configuration index may indicatethat system information set/group/part is changed. In anotherembodiment, ValueTag/identifier/configuration index may identify aparticular configuration of system information set/group/part. When anetwork signals a system information set/group/part identifier and UEdoes not have configuration corresponding to this identifier then UEupdates the system information. In one embodiment, each of this SISet/part/group may contain same parameters but may be valid in differentarea.

While the present disclosure has been shown and described with referenceto various embodiments thereof, it will be understood by those skilledin the art that various changes in form and details may be made thereinwithout departing from the spirit and scope of the present disclosure asdefined by the appended claims and their equivalents.

What is claimed is:
 1. A method for receiving system information (SI) bya user equipment (UE) in a wireless communication system, the methodcomprising: receiving, from a base station (BS) in the wirelesscommunication system, first SI broadcasted periodically, the first SIincluding information indicating whether SI messages for second SI areto be transmitted on demand; transmitting, to the BS, a physical randomaccess channel (PRACH) preamble; receiving, from the BS, a random accessresponse (RAR) message as a response to the PRACH preamble, the RARmessage including an uplink (UL) grant for allocating a UL resource;based on the information indicating that the SI messages for the secondSI are to be transmitted on demand, transmitting, to the BS, an SIrequest message requesting an SI message for the second SI on the ULresource; and receiving, from the BS, the requested SI message for thesecond SI as a response to the SI request message.